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Lysozyme responsive spray-dried chitosan particles for early detection of wound infection Claudia Tallian, Gregor Tegl, Lisa Quadlbauer, Robert Vielnascher, Simone Weinberger, Raymon Cremers, Alessandro Pellis, Johannes W.O. Salari, and Georg M Guebitz ACS Appl. Bio Mater., Just Accepted Manuscript • DOI: 10.1021/acsabm.9b00023 • Publication Date (Web): 19 Feb 2019 Downloaded from http://pubs.acs.org on February 21, 2019
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Lysozyme responsive spray-dried chitosan particles for early detection of wound infection Claudia Tallian†, Gregor Tegl†*, Lisa Quadlbauer†, Robert Vielnascher†,‡, Simone Weinberger,‡, Raymon Cremers§, Alessandro Pellis‖, Johannes W.O. Salari§ and Georg M. Guebitz, †,‡ †University
of Natural Resources and Life Sciences, Vienna (BOKU), Institute for Environmental Biotechnology, Department for Agrobiotechnology (IFA-Tulln), KonradLorenz-Strasse 20, 3430 Tulln an der Donau, Austria. ‡Austrian
Centre of Industrial Biotechnology, Konrad-Lorenz-Strasse 20, 3430 Tulln an der Donau, Austria. §
Netherlands Institute for Applied Scientific Research, Eindhoven, 5612 AP, The Netherlands
‖
Department of Chemistry, University of York, Heslington, York, YO10 5DD, United Kingdom * Corresponding Author:
[email protected] KEYWORDS: Wound infection, N-acetylated chitosan, Lysozyme, Diagnostics, Nacetylation, Enzyme responsive release ABSTRACT Infections are a severe health issue and the need for an early point-of-care diagnostic approach for wound infections is continuously growing. Lysozyme that has shown a great potential as biomarker for rapid detection of wound infection. In this study, spray drying of labelled and derivatized chitosans was investigated for the production of small particles responsive to lysozyme. Therefore, various chitosans, differing in their origin (snow crab, Chionoecetes sp., with medium and low molecular weight or shrimp) were N-acetylated, labeled with reactive black 5 and tested for solubility and spray drying suitability. Reactive black 5 stained Nacetylatyed chitosan (low molecular weight, origin crab) was successfully spray dried and the 1 ACS Paragon Plus Environment
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obtained particles were characterized regarding size, zeta potential and morphology. The particles showed an average hydrodynamic radius of 612.5 ± 132.8 nm. Zeta potential was measured in the context of a later application as infection detection system for wound infections in artificial wound fluid (-6.14 ± 0.16 mV) and infected wound fluid (-7.93 ± 1.35 mV). Furthermore, the aggregation behavior and surface structure were analyzed by using scanning electron microscopy and confocal laser scanning microscopy revealing spherical shaped particles with explicit surface topologies. Spray dried N-acetylated chitosan particles showed a 5-fold increase in lysozyme responsive release of dyed chitosan fragments due to the enhanced surface area to volume ratio when compared to non-spray dried N-acetylated chitosan flakes. Based on these results, the study showed the improved properties of N-acetylated spray dried chitosan particles for future applications for early and rapid infection detection.
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INTRODUCTION Worldwide, wound infections are a severe health issue with 7 to 10% of all surgical wounds that are yearly diagnosed as infected and over 6.5 million patients suffering from chronic wounds in the United States only in 2009. 1,2 Chronic infections develop from traumatic or surgical wounds and healthcare-associated infections with live-endangering consequences such as sepsis3; thus, reliable infection prevention, detection and treatment strategies are needed. In general, wound healing is a complex process involving different phases of hemostasis, inflammation, proliferation and remodeling4. Microbial colonization of the wound is possible during all phases and most infections are identified as polymicrobial5. In the case of infection, the host defenses are not capable of competing the invading organisms resulting in delayed wound healing, increased patient trauma and possibly in the development of chronic wounds6,7. In this context, infections have to be identified rapidly and early enough, whereby signs for clinical diagnosis were described by Cutting and Harding. Delayed healing, offensive odor, discoloration, increase in lesion size, pain or discomfort and prolonged exudate production were described as important signs for the diagnosis of infection.8 However, clinical signs are still seen as controversial, as discussed by Gardner et al.9,10. Therefore, microbiological sampling combined with modern molecular biology tools, hematologic analysis and the analysis of biochemical markers such as bacteria, metabolites or enzymes offer additional potential for reliable and rapid diagnosis11. Various methods for the detection of enzymes as biochemical markers are described, and recently reviewed by Tegl et al.12 comprising aptamers or amperometric sensors, color reactions, antibody trapping and dye release systems, amongst others6,12. These systems are based on elevated activities of certain enzymes in human wound fluid of infected wounds, whereby these enzyme activities refer to the current wound status. Biomarkers such as lysozyme, human neutrophil elastase (HNE) and myeloperoxidase (MPO) are frequently 3 ACS Paragon Plus Environment
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discussed in this regard13 while among these enzymes only lysozyme is exclusively produced by the human immune system, as a direct reflection of the host’s immune response14. Considerably increased activity of lysozyme in postoperative wounds and decubitus wound fluids was reported by Hasmann et al. (4830 ± 1848 U/mL compared to non-infected wounds 376 ± 240 U/mL), which demonstrated the potential of lysozyme as basis for the development of new infection detection systems.15,16 Lysozymes are glycoside hydrolases found in GH families 19, 22, 23, 24 and 46, commonly hydrolyzing the glycosidic linkage between the N-acetyl glucosamine and N-acetylmuramaric acid units of peptidoglycan of bacterial cell walls.17 Additionally, lysozyme was described to hydrolyze chitosan, a biopolymer consisting of β(1,4)-linked units of N-acetyl glucosamine and glucosamine17, which offers an alternative lysozyme responsive biomaterial overcoming the bacterial origin of peptidoglycan and therefore the possibility of an immune response.6,12 The hydrolysis rate of chitosan by lysozyme is influenced by the physico-chemical properties of the chitosans such as the degree of N-acetylation (DA) as well as the distribution of acetyl groups along the polymer chain (PA).18 Chemical modifications of chitosans successfully led to the development of chitosan-based lysozyme substrates, enabling the detection of increased lysozyme activities in human wound fluids19. Furthermore, chitosan and chitosan derivates have been extensively studied regarding biocompatibility and biotoxicity20,21. Published studies on chitosans toxicity showed a strong dependency on the type of chemical modification and application routes21–23. Nonetheless, chitosan is widely regarded as being a non-toxic material and products in dietary applications are approved in Japan, Italy and Finland. Additionally, chitosan as wound dressing material was already approved by the FDA.21 Based on this previous report, the present work investigates the synthesis of a functionalized chitosan-based material suitable for spray drying, resulting in particles that enable a simple and rapid visual lysozyme detection in wound fluids. Chitosans of different properties were 4 ACS Paragon Plus Environment
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chemically modified to ensure high sensitivity towards lysozyme degradation and, at the same time, have efficient processability for spray drying. The chitosan starting materials were characterized, modified by N-acetylation and labeled using reactive black 5. The spray dried enzyme substrate offered a second-generation substrate for the detection of lysozyme, greatly accelerating the visual response of in vitro infection detection.
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MATERIALS AND METHODS Materials. Crab chitosans 90/5 of Chionoecetes sp. (low molecular weight; LMW) was purchased from Heppe Medical Chitosan GmbH (Germany), chitosans from shrimp shells and from crab shells (80/20, medium molecular weight; MMW) were purchased from Sigma Aldrich (Germany). All other chemicals were of analytical grade from Sigma Aldrich (Germany) and used as received, if not otherwise stated.
Size Exclusion Chromatography (SEC) characterization of chitosans. Purchased chitosans (crab LMW, shrimp and crab MMW) were characterized regarding the number average molecular weight (Mn), the weight average molecular weight (Mw) and the polydispersity (PD) via size exclusion chromatography. Samples were dissolved in a mixture of acetate buffer with 0.15 M acetic acid, 0.1 M sodium acetate, 0.4 mM sodium azide in ultrapure water (mobile phase) to a final concentration of 1.0 mg/mL. An Agilent 1100 Series chromatography system (Agilent Technologies, United States) equipped with an Agilent 1200 G1362A refractive index detector (Agilent Technologies, United States) and a TSKgel G5000PWxl column (Tosoh Bioscience, Montgomeryville, PA, USA) was used for the analysis. System calibration was performed using a pullulan standard (Fluka, Switzerland) in the 342 Da to 800 kDa 6 ACS Paragon Plus Environment
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range. The injection volume was of 100 µL and the mobile phase flow rate of 0.3 mL/min at 21 °C.
Synthesis of N-acetylated chitosans. N-acetylation of chitosans (crab LMW, shrimp and crab MMW) was performed according the procedure of Tegl et al.19. Briefly, the chitosans were dissolved in 10% acetic acid to a final concentration of 1% w/v followed by a 1:1 dilution in ethanol. The mixtures were then stirred for 10 min at 21 °C. Subsequently, acetic anhydride was added in the concentrations of 0.50, 0.75, 1.00 and 1.25 mol equivalent. The calculation was based on the glucosamine units of the polymers. The mixtures were further stirred for 1 h and the pH was adjusted to 8.0 using 1 M NaOH. N-acetylated chitosans were then washed to a neutral pH with ddH2O and lyophilized prior to use.
Nuclear Magnetic Resonance Spectroscopy (NMR). The degree of acetylation (DA) was determined by using 1H nuclear magnetic resonance on a Bruker Avance II 400 spectrometer, with a resonance frequency for 1H of 400.13 MHz. The system was equipped with a 5 mm observe broadband probe head with z-gradients. Samples were dissolved in a mixture of D2O and 1% acetic acid-D4, if not otherwise specified. DAs were calculated using the integrals of the proton peaks H2 of the deacetylated monomer and the three proton peaks of the acetyl groups, according to the protocol published by Tegl et al.19 (equation 1). Equation (1):
( (
𝐷𝐴[%] = 1 ―
𝐻2𝐷 𝐻2𝐷 +
𝐻𝐴𝑐 3
)) × 100 7
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H2D: Integral of the H2 proton HAc: Summation of integrals of the N-acetyl group Attenuated total reflection Fourier-transform infrared-spectroscopy (ATR-FTIR). Nacetylated chitosans samples were analyzed via Fourier transform infrared spectroscopy in attenuated reflection mode (ATR-FTIR) using a Spectrum 100 Perkin Elmer FT-IR spectrometer (Massachusetts, USA). Spectra were normalized between 950 and 1050 cm-1, baseline corrected and compared with spectra of untreated chitosans. The amide I band at 1640 cm-1 and the amide II band at 1560 cm-1 were considered for the analysis of the DA.19 Preparation of chitosan substrates. Chitosans substrates for further spray drying were produced by covalent staining of N-acetylated chitosans with Reactive Black 5 (RB5). Therefore, 100 mg of N-acetylated chitosans were swollen in ultrapure water for 20 min. Afterwards, a 0.5% (w/v) solution of RB5 in ultrapure water and a solution of 2.5% (w/v) Na2SO4 and 1% (w/v) NaCO3 were added to the swollen chitosans. The solution was incubated for 10 min at 21 °C, followed by 1 h at 65 °C. After incubation, the samples were centrifuged and rinsed with ultrapure water to remove unbound stain. Samples were lyophilized and stored until further use. Spray drying of chitosans substrates. Spray drying was performed with a Büchi Mini Spray Dryer B-290. First, aqueous solutions of the modified chitosans substrates were prepared. The solvent was 1 weight percent (wt%) acetic acid solution in water. 0.5 wt% of the chitosan substrate solution were prepared in the acidic solvent. The chitosans solution was stirred until a clear solution was obtained. The solutions were filtered through a 5 µm filter before spray drying. The chitosans solution was then sprayed in the spray dryer with pump setting 10 (3.3 mL/min). The solution droplets were dried to form particles under the following conditions. A nitrogen flow of ~0.1 L/s passed through the drying column. The aspirator setting was 70% and
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the pressure of 50 mbar. The inlet temperature of the gas flow was 205 °C. Chitosans powder particles were produced with a yield of ~59%. Scanning electron microscopy (SEM). The surface morphology of N-acetylated chitosans flakes and spray dried N-acetylated chitosans particles was determined using SEM. All images were acquired by collecting secondary electrons on a Hitachi 3030TM (Metrohm INULA GmbH, Austria) working at Energy Dispersive Xray Spectrom (EDX) acceleration voltage. For the comparison of DLS based size distribution with obtained SEM results, the pictures were further processed by the use of ImageJ software for particles smaller than 3 µm to investigate the nano fraction of the samples24. The obtained data on size were processed using Image J software24 to calculate the relative frequencies of the sub-micro sized particles and the micro fraction of stained N-acetylated chitosan particles. Laser Doppler velocimetry (LDV). Laser Doppler Velocimetry (LDV) was used to determine the electrophoretic mobility and calculate the zeta potential (ζ) of spray dried chitosans particles using the Henry equation25. Equation (2):
𝑈𝐸 =
2𝜀 𝑓(𝐾𝑎) 3𝜂
ζ: Zeta potential (mV) UE: Electrophoretic mobility (m² s-1 V-1) Η: Viscosity (Pa s) ε: Dielectric constant (F m-1) f(Ka): Henry’s function. For data evaluation, the Smoluchowski approximation26 was used, whereby f(Ka) is defined as 1.5. Therefore, ζ of chitosan particles was measured using Malvern Zetasizer Nano ZS (Malvern Instruments GmbH, Germany), with a 15x dilution in 1x PBS buffer, in artificial wound fluid (AWF, human serum albumin 2% w/v, sodium chloride 111.5 mM, sodium hydrogen carbonate 17.5 mM, sodium lactate 11 mM, glucose 1.2 mM, calcium chloride 2.2 mM, magnesium 9 ACS Paragon Plus Environment
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chloride 0.9 mM, urea 9 mM and potassium chloride 4.4 mM, pH 7.2 with an average lysozyme activity of 83.33 µkat/mg and in 1:10 diluted wound fluids (WF) in 0.9% NaCl solution. For each sample three measurements with a minimum of 20 runs were averaged and for each measurement the optimum attenuator position and number of runs was optimized automatically. Outliers were tested using a modified Thompson tau test and excluded from results. Dynamic light scattering (DLS). Hydrodynamic radius (RH) was measured using dynamic light scattering (DLS) performed with a Wyatt DynaPro NanoStar detector (Wyatt Technology Europe, Germany). Measurements were performed in disposable cuvettes with diluted spray dried chitosans particle samples in 66 mM potassium phosphate buffer pH 6.2. Samples were measured three times with 20 acquisitions and 2 s acquisition time for each measurement. Obtained results were statistically tested for outliers using a modified Thomson tau test and averaged. Confocal laser scanning microscopy (CLSM). Staining efficiency was determined by the visualization of the dye distribution using a FV1000 Fluoview (Olympus, US) confocal laser scanning microscope equipped with an UPLSAPO 60x W aperture objective (Olympus, US). For fluorescent imaging of stained chitosans substrates and spray dried particles a laser light wavelength of 405 nm (λem 426-526 nm) was used. The signal/noise ratio of each individual channel, sample and field of view, the laser intensity, the photomultiplier gain, as well as the offset were optimized for each sample individually. Pictures of each sample were taken from the fluorescent (F) and the bright field (BF) microscopy channel, additionally to the corresponding overlay (OVL). The obtained data on particle size were evaluated using Image J software.24 Lysozyme activity assay. The determination of lysozyme activity was based on the method of Shugar et al.27. Therefore, cells of Micrococcus lysodeikticus were suspended in 66 mM potassium phosphate buffer pH 6.2 to obtain a final concentration of 0.01% (w/v). For UV/Vis 10 ACS Paragon Plus Environment
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spectroscopy analyses 290 µL of bacteria suspension were mixed with lysozyme solutions of different concentrations (0.1, 0.05, 0.01, 0.0075, 0.005, 0.0025, 0.001 mg/mL) and the increasing transparency was measured at 450 nm using a Tecan Infinite 200 Pro plate reader (Tecan Trading AG, Switzerland) for 10 min at 25 °C. For calculations of the enzyme activity one unit of lysozyme was defined to decrease the absorbance at 450 nm by 0.001 per minute at pH 7.0. Wound fluid (WF) activity assay. The activity of wound fluids19 was measured with the same method as lysozyme activity. Used WF (A and B) were tested, whereby WF_A clinically described as non-infected15,16 had low lysozyme activity and was chosen as negative control. The permission for wound fluid collection and scientific usage was obtained from Medisch Ethische ToetsingCommissie Twente (Netherlands, Enschede) under the statement number METC/14213.haa. Enzyme responsive degradation studies of chitosan based substrates. Produced chitosans substrates with covalently bound RB5 as well as spray dried and stained chitosans particles were tested regarding lysozyme responsive color release. Therefore, 2 mg of each sample were suspended in 0.5 mL of 1 mg/mL lysozyme solution with an average activity of 83.333 µkat/mg in 66 mM potassium phosphate buffer pH 6.2, in AWF or in 1:10 diluted WF in 0.9% NaCl solution. Experiments were performed in triplicates. After suspension, samples were incubated for 24 h at 37 °C. Samples were taken after 0, 1, 2, 4, 6 and 24 h. As negative control either potassium phosphate buffer, AF without lysozyme or 1:10 diluted WF_A were used corresponding to the tested sample. For each time point samples were centrifuged and 200 µL of the supernatant were removed for UV/Vis measurements at 597 nm (absorbance maxima of RB5) using a Tecan Infinite 200 Pro plate reader (Tecan Trading AG, Switzerland). After the measurements, the aliquots were returned to the reaction mix for further incubation.
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RESULTS AND DISCUSSION Lysozyme has been previously investigated as potential biomarker for the detection of wound infections.15,19 Strategies involving peptidoglycan from bacterial cell walls as lysozyme substrate showed limitations due to the risk of direct contact to patient wounds potentially inducing immune responses. Circumventing this bottleneck, detection systems based on chitosans where previously published including composite material wound dressings28–30, hydrogels31 and particles32
19.
However, there is a need for materials allowing a simple and
flexible integration into a variety of sensor systems. Hence, the formulation of spray dried Nacetylated chitosans particles was hypothesized to further improve lysozyme induced hydrolysis of chitosan for the application in wound infection detection. Hereby, spray drying and the corresponding increase of the surface area to volume ratio due to the formation of atomized droplets and water evaporation is described as beneficial for the increase in release properties of the material.33–35 Moreover, the higher surface area to volume ratio can facilitate the contact and penetration with buffer, as previously reported by Panyam et al.36, or within this study with wound fluid. Characterization of raw materials and N-acetylation products. Native chitosans derived from
crab (MMW and LMW) and shrimp shells were investigated regarding their molecular weights using SEC-MALLS. High deviations based on the origin of the used chitosan were observed, ranging from 485.5 ± 3.7 kDa (crab MMW) over 236.69 ± 4.5 kDa (shrimp) to 121.8 ± 7.0 kDa (crab LMW) for the number average molecular weights (Mn) (see SI, Fig. S1A) (Tab. 1); the weight average molecular weights (Mw) showed comparable results (SI, Fig. S1B). similar polydispersity values (SI, Fig. S1C) were obtained for chitosans of all tested origins. Table 1. Experimental overview of tested chitosans, whereby Mn refers to the number average molecular weight in kDa, Mw to weight average molecular weight, PD to polydispersity, DA to the degree of acetylation in %, RB5 staining to the staining with reactive black 5, SD to spray drying, RH to the hydrodynamic radius in nm,
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ID to the sample ID and n.d. to not determined. +/- are indicating the success of the performed experiments for the tested material. Chitosans origin
Mn [kDa]a
Mw [kDa]a
PDa
Crab MMW
485.5 ± 3.7
1834.2 ± 203.5
3.78 ± 0.39
Shrimp
236.6 ± 4.5
835.4 ± 27.6
3.53 ± 0.05
Crab LMW
121.8 ± 7.0
370.5 ± 74.2
3.07 ± 0.81
a b
RB5 staining + + + + + +
Solubility
SD
-
-
Lysozyme Release -
+
+
+
+
-
-
-
-
RH [nm] 612.5 ± 132.8 -
DA [%]b 36 37 40 n.d. 36 46 n.d. n.d. 37
ID A B C D E F G H I
49
J
51 n.d.
K L
calculated via SEC using pullulan standards calculated via 1H-NMR
The N-acetylated chitosans were analyzed by 1H-NMR (Tab. 1, Fig. S2) and ATR-FTIR (Fig. 1) showing significant shifts in the amide carbonyl stretching band (1640 cm-1), the NH2+ deformation band (1590 cm-1) and the amide N-H stretching band (1540 cm-1) indicating successful N-acetylation.
Figure 1. ATR-FTIR spectra (normalized in the region 1025 cm-1 and baseline corrected) of native crab LMW chitosans, and N-acetylated crab LMW chitosans (sample J), whereby the increase in the absorbance of the amide stretching band is at 1640 cm-1 and the carbonyl stretching band at 1540 cm-1.
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spectra showed that N-acetylation with 1.0 (shrimp) and 1.25 (crab LMW, shrimp
and crab MMW) mol equivalent of acetic anhydride was successful (Tab. 1); however, the calculation of the DA was not possible due to insoluble fractions of synthesis products during sample preparation for 1H-NMR. N-acetylation using 0.50, 0.75 and 1.00 mol equivalent resulted in DAs between 36 and 51%, whereby the increase in applied acetic anhydride showed the expected corresponding increase in DA values within one type of chitosans. An impact of the chitosan’s origin on the DA could not be determined when comparing the DA results for shrimp, crab MMW or crab LMW using equivalent amounts of acetic anhydride. Based on these findings, all successfully acetylated chitosans were used for further functionalization, i.e. staining with RB5, for the optimization regarding early wound infection detection and therefore for spray drying and lysozyme response. N-acetyl chitosans functionalization and solubility studies. N-acetylation of chitosans was previously described to be a suitable method for the increase of the lysozyme hydrolysis rate of this naturally derived biopolymer.37 N-acetylated chitosans were labeled with RB5 to allow a simple visual detection of lysozyme activity based on the release of stained fragments from the functionalized polymer. After staining, N-acetylated chitosan substrates were tested for their solubility and suitability for spray drying (Tab. 1). For the labeling process, reactive black 5 was chosen, a reactive vinylsulfone dye forming a vinyl intermediate under basic conditions, which subsequently reacts with a given nucleophile. Using this approach, previous labeling studies using RB5 revealed the best results regarding leaching and homogenity.19 Therefore, RB5 labeling was conducted and the previous published results could be confirmed within this study using CLSM to investigate the homogeneity of dye saturation of the N-acetyl chitosan substrates (Fig. 2A-C). Images showed flake shaped structures of sample J before spray drying, whereby fluorescent images confirmed the homogenous dye distribution over the complete 14 ACS Paragon Plus Environment
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material. Despite the fact that homogenous staining was observed for all N-acetylated chitosan samples, only sample J showed complete solubility in 1 wt% acetic acid solution in water required for spray drying.
Figure 2. Confocal laser scanning microscope images of RB5 stained N-acetylated crab LMW chitosans flakes of sample J of (A) the bright flied channel, (B) the fluorescent channel (laser light wavelength of 405 nm, λem 426526 nm), and (C) the corresponding overlay and images of the RB5 stained spray dried N-acetylated chitosan particles JSD of (D) the bright flied channel, (E) the fluorescent channel (laser light wavelength of 405 nm, λem 426-526 nm), and (F) the corresponding overlay. Scale bar refer to 100 µm.
Enzyme activity of lysozyme and wound fluids. The enzyme activity for lysozyme of hen egg white with 846.67 µkat/mg, non-infected (WF_A) and infected (WF_B) wound fluids was tested using an enzyme activity assay based on the method of Shugar et al.27. The obtained activities were considerably different in for lysozyme, non-infected 33.89 ± 5.36 µkat/mL WF_A and in infected WF_B 301.17 ± 5.53 µkat/mL confirming the potential for infection detection. Spray drying and characterization of product. Spray drying to micro-particles is described as a complex process fully controlling the mechanism of component radial distribution during 15 ACS Paragon Plus Environment
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the drying process. Additionally, surface activity is seen as a major driving factor for successful spray drying, as it can lead to preferential absorption of components on the droplet surface which can cause a diffusional flux toward the surface.38 Accordingly, spray drying of solubilized sample J was performed and the obtained spray dried particles (JSD) were characterized regarding particle size, surface potential and aggregation behavior, morphology and staining homogeneity. The particle size was analyzed in potassium phosphate buffer pH 6.2, mimicking the conditions of AWF and WF to a minor degree, and showed an average hydrodynamic radius of 612.5 ± 132.8 nm, indicating that a submicron fraction is present (Fig. 3). However, RB5 stained spray dried particles (JSD) showed a large micro fraction (Fig. 4), DLS measurements are limited to a submicron range. Therefore, size information was additionally obtained by SEM and CLSM analysis. Additionally, the intense blue color of JSD particles act as limiting factor for DLS experiments resulting in high standard deviations.
Figure 3. Intensity distribution obtained via dynamic light scattering of spray dried N-acetylated crab LMW chitosans (JSD) measured in 66mM potassium phosphate buffer pH 6.2 showing two significant different particle species; Species 1 RH about 4 nm; species 2 RH about 200 nm.
The intensity distribution of JSD revealed a polydisperse behavior, whereby a larger particle species dominates the distribution, as two significant different particle species can be observed
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(species 1 RH about 4 nm; species 2 RH about 200 nm) in Fig. 3. However, SEM (Fig. 4) and CLSM images (Fig 2.) showed no agglomeration or aggregation of the particles.
Figure 4. Scanning electron microscopic images of RB5 stained N-acetylated crab LMW chitosans flakes of sample J with (A) 100x, (B) 1000x, and (C) 2000x magnification and images of the RB5 stained N-acetylated crab LMW chitosans spray dried particles of sample JSD with (D) 100x, (E) 1000x, and (F) 2000x magnification.
SEM images showed sample heterogeneity with particle sizes ranging between 244.6 nm and 4.38 µm, which supports the DLS data regarding the presence of a submicron fraction, as well as structural information. Microscopy based particle size was evaluated separately for the submicron and the micro fraction (Fig. 5) of JSD particles. The calculated average particle radius was 617.8 ± 194.0 nm; however, particles with sizes smaller than 200 nm could not be observed due to occurring image resolution limits and corresponding blur at higher magnifications caused by instrument limitations of the SEM instrument used. Further higher magnifications and therefore higher energies negatively affected sample stability leading to significant particle destruction, as a result images were obtained at magnifications of 100, 1000 and 2000x. In direct comparison obtained SEM and DLS based radii showed significant comparability, further supported by the displayed intensity distribution (Fig. 3) and the relative frequency distribution 17 ACS Paragon Plus Environment
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(Fig. 5). In general, the presence of the submicron fraction is seen as highly benefitting due to the increased surface area when compared to the same volume of the materials. This effect was previously described by Biener et al.39 and leads to an hypothesized enhanced reaction possibility due to the elevated potential for lysozyme to interact with the presented N-acetylated chitosan particle surface compared to the significant smaller surface of microparticles of the same volume. Therefore, the application of JSD particles in future in vitro test systems should offer rapid infection detection due to the enhanced reaction possibility and hence reaction velocity.
Figure 5. (A) Calculated relative frequency distribution based on scanning electron microscopic images of RB5 stained spray dried N-acetylated chitosan particles (sample JSD) processed with Image J software including the submicron and micro fraction of the sample (delimited with dotted line). (B) Obtained radii of RB5 stained spray dried N-acetylated chitosan particles (JSD) using DLS (hydrodynamic radius in nm) and scanning electron microscopy (radius in nm) of the submicron fraction.
JSD particles were spherically shaped with porous fracture surfaces showing significant topologies. Porous fracture surfaces of the particles are hypothesized to lead to an enhanced lysozyme responsive release of RB5 due to the increased contact area for lysozyme attack based 18 ACS Paragon Plus Environment
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on the increase of the surface area to volume ratio compared to N-acetylated chitosans flakes before spray drying.36,38 Therefore, stain distribution was further investigated after spray drying by using CLSM (Fig. 2). Compared to the homogeneous staining before spray drying, JSD particles showed a highly homogeneous labeling, whereby surface topology impacts where visible. Additionally, zeta potential measurements were performed analyzing the aggregation behavior and particle stability (Fig. 6).
Figure 6. Zeta potential of spray dried N-acetylated crab LMW chitosans particles sample JSD measured in 66 mM potassium phosphate buffer pH 6.2, artificial wound fluid with a lysozyme activity of 83.33 µkat/mg, wound fluid with low (WF_A, 33.89 ± 5.36 µkat/mL) and high (WF_B, 301.17 ± 5.53 µkat/mL) lysozyme activity.
A zeta potential (ζ) between +3.42 ± 0.12 and -11.11 ± 2.09 mV was obtained, highly influenced by the used solvent (buffer, AWF, WF_A or WF_B). ζ values between -10 and -20 mV are considered to refer to relatively stable particles40. However, as previously discussed, no aggregation behavior could be seen in SEM and CLSM studies (Fig. 2 & 4). Ionic strength induced changes from positive to negative ζ are due to the compression of the electric double layer induced by an increasing presence of ions.40 This effect can be clearly seen comparing the ζ in potassium phosphate buffer pH 6.2 (+3.42 ± 0.12 mV) and AWF (-6.14 ± 0.16 mV) or WF (WF_A -11.11± 2.09 mV; WF_B -7.93 ± 1.35 mV). AWF has higher ionic strength due to the composition compared to the potassium phosphate buffer; however, compared to the values measured in WF, the ionic strength of infected WF_B is lower than of non-infected WF_A. This effect can be caused by the high activity of lysozyme and other enzymes (MPO, HNE) 19 ACS Paragon Plus Environment
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present in infected WF and the enzymes surface charges41, which show a significant impact on the ionic strength.42 This theory is supported by the comparison of the AWF (lysozyme activity of 83.33 µkat/mg) with non-infected WF_A (lysozyme activity of 33.89 ± 5.36 µkat/mL), whereby the higher lysozyme activity in AWF also possibly lead to a decrease in the ζ compared to WF_A. Furthermore, for later applications as infection detection system, negative ζ values are seen as beneficial regarding the reduction of possible arterial clogging induced by direct wound contact in case of mishandling, which was recently reported by Honary & Zahir43 and Sonavane et al.44. Lysozyme detection. Based on the aimed approach applying JSD particles for early stage wound infection detection, the lysozyme mediated release of RB5 stained fragments was investigated in potassium phosphate buffer pH 6.2, AWF and infected WF_B (Fig. 7). Despite slightly faster hydrolysis at pH 5 compared to pH 6.2 was previously reported using Nacetylated shrimp chitosans19, HMC based JSD particles showed complete dissolution in pH 6.2 after 24 h incubation. In general, spray drying increased the release behavior for all tested solvents, whereby maximum RB5 release was observed after incubation of JSD particles in 66 mM potassium phosphate buffer pH 6.2 with a lysozyme activity of 83.33 µkat/mg. Enhanced lysozyme mediated release of RB5 from JSD particles might result from the increased surface area. The increase of the surface/volume ratio can be associated with the facilitation of buffer contact and penetration into the particles. Furthermore, faster diffusion of monomers and oligomers out of the particles is simultaneously enhanced, which can be compared to results previously reported by Panyam et al. for spray dried poly(lactic-co-glycolic) acid particles.36 On the other hand, random distribution of the N-acetyl groups could provide a substantial amount of lysozymebinding sites.45 Lysozyme responsive release in AWF and WF_B showed comparable results, 20 ACS Paragon Plus Environment
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whereas the release of stained chitosan was decreased incubating in lysozyme containing potassium phosphate buffer pH 6.2. This data correlates to the results of Laser-Doppler velocimetry, since the ζ showed a significant impact on lysozyme-binding. The reduced ionic strength due to the possible attachment of ions on the enzyme surface, e.g. in case of AWF chloride or lactate, is hypothesized to reduce the binding properties, which leads to a decrease in released RB5 from JSD particles. Nonetheless, the release studies tested in WF of infected wounds led to positive results regarding the enhancement of fast lysozyme mediated release using the spray drying particles, showing a 5 fold increase compared to our previous studies.19 Therefore, the application in a rapid in vitro stand-alone infection detection approach is seen as promising, offering fast detection without direct wound contact of the material.
Figure 7. Lysozyme responsive release of RB5 from stained N-acetylated crab LMW chitosans sample J before and after spray drying (JSD). (A) Increase of absorbance [a.u.] at 597 nm over an incubation time of 24 h in 66 mM potassium phosphate buffer pH 6.2 with a concentration of 1 mg/mL lysozyme (83.33 µkat/mg). (B) Increase of absorbance [a.u.] at 597 nm over an incubation time of 24 h in artificial wound fluid with a concentration of 1 mg/mL lysozyme (83.33 µkat/mg). (C) Release profile displayed as increase of absorbance [a.u.] over time [h] at 597 nm in positive wound fluid (WF_B) with an activity of 301.17 ± 5.53 µkat/mL.
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CONCLUSIONS In this study, chitosans of different physicochemical properties were chemically functionalized and tested upon their suitability for particle formation by spray drying. Reactive black 5 stained crab LMW N-acetyl chitosan substrates were successfully spray dried and the obtained particles showed an average hydrodynamic radius of 612.5 ± 132.8 nm, indicating that a submicron fraction is present. The zeta potential and surface charge were investigated in relation to later applications as infection detection system for wound infections, whereby the negative ZP indicated a high biocompatibility. Furthermore, aggregation behavior and surface structure were analyzed revealing spherical shaped particles with explicit surface topologies. The obtained increased surface area to volume ratio correlated to the results of the in vitro release studies. Hereby, spray dried N-acetyl chitosan particles showed a 5 times faster lysozyme mediated release of reactive black 5. Based on the results, this approach showed the potential for the application of spray dried N-acetyl chitosan particles for wound fluid based in vitro early infection detection. The spray dried lysozyme substrate greatly improved the stability of the detection material, thus facilitating its integration in different infection detection systems such as rapid in vitro stand-alone devices without direct patient contact. ASSOCIATED CONTENT Supporting Information The supporting information is available free of charge on the ACS Publication websites. SEC-MALLS analysis of native chitosans, 1H-NMR analysis of N-acetylated crab LMW chitosans (PDF) AUTHOR INFORMATION Corresponding Author *Tel.: 604-822-4626. * E-mail:
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Notes The authors declare no competing financial interest. ORCID: Claudia Tallian: 0000-0002-0790-3881 Robert Vielnascher: 0000-0002-5160-8070 Alessandro Pellis: 0000-0003-3711-3087 Gregor Tegl: 0000-0002-4242-1693 ACKNOWLEDGMENTS Wound fluids and facilities for wound fluid studies were kindly provided by Qualizyme Diagnostics GmbH. We also want to thank Karin Wieland (Vienna University of Technology, Vienna, Austria) for scientific input on FTIR results interpretation and Clemens Gamerith (ACIB GmbH, Graz, Austria) for technical support during wound fluid studies. This work was performed within the European project Infact and has received financial funding from the European FP7-programme grant agreement no. 604278 and from the NÖ Forschungs- und Bildungsges.m.b.H. (NFB) and the provincial government of Lower Austria through the Science Calls (Project ID: SC16-024). The Austrian Centre of Industrial Biotechnology (ACIB) is gratefully acknowledged. Alessandro Pellis thanks the FWF Erwin Schrödinger fellowship (grant agreement: J 4014-N34) for financial support. REFERENCES: (1)
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Graphical abstract
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Reactive black 5 functionalized N-acetylated chitosan substrates were designed suitable for spray drying. The resulting lysozyme responsive particles enabled a greatly improved detection of the infection biomarker which renders it a robust material for applications in rapid in vitro infection detection systems. 338x190mm (96 x 96 DPI)
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